Appendix D – First text passage (Bats)

Appendix D – First text passage (Bats)

(A word list with definitions is available on page 3 – last page)

Bats really stand out in the animal world. They are the only mammals that can fly, and they live much of their lives hanging upside down. Most species are active only from dusk until dawn, spending their days in dark caves. Many bats have developed adaptations or adaptive traits that let them find their way (and their prey) in complete darkness. Bats have survived as a group for more than 50 million years, longer than most other modern animals. All bat species are part of a phylogenetic order called Chiroptera, which comes from the Greek words cheir (“hand”) and pteron (“wing”). There are more than 1,000 bat species in the world, making them one of the most widespread orders of mammals.

Traditionally, bat species are divided into two suborders or subcategories: Megachiroptera (megabats) and Microchiroptera (microbats). Most megabat species are frugivores (fruit eaters) or nectavores (nectar drinkers) and look a lot like other mammals, with large eyes, small ears, and extended snouts. In contrast, most microbat species are insectivores and have a unique facial appearance, with large ears and peculiarly shaped, stubby snouts. One microbat that is an exception to this is the vampire bat, which feeds not on insects, but on mammals’ blood. It can consume half its body weight in blood in one feed.

While megabats have good eyesight, microbats use echo-location for navigation and finding prey. Also, the two suborders differ in terms of where they live: megabats are found only in Africa, Asia, and Australia, whereas microbats live all over the world. Although most scientists agree that the division of bat species into two suborders is a useful approach to studying bats, the phylogenetic relationship among the different groups of bats has been the subject of much debate.

Although bats and birds both fly, a bat wing actually has more in common with a human arm than a bird wing. A bird’s wing has fairly rigid bone structure, and the main flying muscles move the bones at the point where the wing connects to the body. In contrast, a bat has a much more flexible wing structure. It is similar to a human arm and hand, except it has a thin membrane of skin (called the patagium) extending between the “hand” and the body, and between each finger bone. Bats can use the wing like a hand, essentially moving through the air like a swimmer moves through water. The rigid bird wing is more efficient at providing lift, but the flexible bat wing allows for greater manoeuvrability.

To help them navigate and find their prey in the dark, microbat species have developed a remarkable system called echolocation. By emitting high-pitched sound waves and listening to the echoes, bats can determine with great precision the location of an object, how big it is, and the direction in which it is moving. Bats calculate the distance of the object by the amount of time it takes for the sound wave to return and the exact position of the object by comparing when the sound reaches its right ear to when the sound reaches its left ear. Similarly, a bat can tell how big an insect is based on the intensity of the echo: a smaller object will reflect less of the sound wave, and so will produce a less intense echo.

Although they hunt all night, bats will pass the daylight hours hanging upside down from a secluded spot, such as a cave or a hollowed-out tree. There are a couple of different reasons why bats roost this way. First of all, hanging upside down puts them in position for take-off, which is important because bats cannot launch themselves into the air from the ground. It is also a great way to hide from danger. During the hours when most predators are active, bats congregate (gather) where few animals look and most cannot reach. Although snakes, possums, and raccoons sometimes hunt bats, birds of prey are the main predator of bats. Most bat species roost in the same location every day, clustering with other bats for warmth and security.

Bats have a special physiological adaptation that enables them to hang upside down. A bat’s talons work like human fingers, except that humans must contract muscles to grasp an object, whereas bats must do the opposite – relax their muscles. When humans grasp an object, they contract several arm muscles, which in turn pull tendons connected to their fingers, which pull the fingers closed. To hang upside down, a bat opens its talons to grab hold of the surface, and then simply lets its body relax. The weight of the upper body pulls down on the tendons connected to the talons, causing them to clench. Since it is gravity that keeps the talons closed, instead of a contracted muscle, the bat doesn't have to exert any energy to hang upside down.

Like all mammals, bats maintain their body temperature internally. However, unlike most mammals, bats allow their body temperature to sink to the ambient temperature whenever they are not active. As their temperature drops, they enter a torpor state (state of physical inactivity), in which their metabolism slows down considerably. By reducing their biological activity and not maintaining a warm body temperature, bats conserve energy. This ability is important because flying all night is hard work. When the temperature is cold for long periods during the winter months, some bats enter a deeper torpor state called hibernation. Other bat species follow a yearly migration pattern, traveling to cooler climates in the warm months and warmer climates in the cool months. This is why some regions experience “bat seasons” every year.

Many people have a negative reaction to bats, and it's easy to see why. Bats have also long been tied with vampires. While Bram Stoker was the first to have Dracula transform into a bat, a popular story titled Varney the Vampire published in 1845 is actually the earliest evidence we have of popular bat-vampire connection. Also, just by virtue of their appearance and behaviour, bats play into a number of human fears.

However, insectivorous bats are the best bug killers on the planet, For example, a famous colony of more than 20 million Mexican free-tail bats that lives in Bracken Cave, Texas will eat up to 200 tons of insects in a night. Nectavoric bats are also prolific plant pollinators. Many species feed on plant nectar, gathering pollen on their bodies as they feed and helping the plant to disperse its seed when they visit other plants.

Word list:

• 
  Phylogenetic – study of the history, development and relationships among groups of genetically-related organisms
  
• 
  Torpor – state of physical or mental inactivity; lethargy